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Sop.v
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Sop.v
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(** Arithmetic and logical operators for Stanlight; a cut down version C/Clight Cop.v *)
Require Import Coqlib.
Require Import AST.
Require Import Integers.
Require Import Floats.
Require Import Values.
Require Import Memory.
Require Import Ctypes.
Require Archi.
(** * Syntax of operators. *)
Inductive unary_operation : Type :=
| Onotbool : unary_operation (**r boolean negation ([!] in C) *)
| Onotint : unary_operation (**r integer complement ([~] in C) *)
| Oneg : unary_operation (**r opposite (unary [-]) *)
| Oabsfloat : unary_operation. (**r floating-point absolute value *)
Inductive binary_operation : Type :=
| Oadd : binary_operation (**r addition (binary [+]) *)
| Osub : binary_operation (**r subtraction (binary [-]) *)
| Omul : binary_operation (**r multiplication (binary [*]) *)
| Odiv : binary_operation (**r division ([/]) *)
| Omod : binary_operation (**r remainder ([%]) *)
| Oand : binary_operation (**r bitwise and ([&]) *)
| Oor : binary_operation (**r bitwise or ([|]) *)
| Oxor : binary_operation (**r bitwise xor ([^]) *)
| Oshl : binary_operation (**r left shift ([<<]) *)
| Oshr : binary_operation (**r right shift ([>>]) *)
| Oeq: binary_operation (**r comparison ([==]) *)
| One: binary_operation (**r comparison ([!=]) *)
| Olt: binary_operation (**r comparison ([<]) *)
| Ogt: binary_operation (**r comparison ([>]) *)
| Ole: binary_operation (**r comparison ([<=]) *)
| Oge: binary_operation. (**r comparison ([>=]) *)
Inductive incr_or_decr : Type := Incr | Decr.
(** * Type classification and semantics of operators. *)
(** Most C operators are overloaded (they apply to arguments of various
types) and their semantics depend on the types of their arguments.
The following [classify_*] functions take as arguments the types
of the arguments of an operation. They return enough information
to resolve overloading for this operator applications, such as
``both arguments are floats'', or ``the first is a pointer
and the second is an integer''. This classification is used in the
compiler (module [Cshmgen]) to resolve overloading statically.
The [sem_*] functions below compute the result of an operator
application. Since operators are overloaded, the result depends
both on the static types of the arguments and on their run-time values.
The corresponding [classify_*] function is first called on the
types of the arguments to resolve static overloading. It is then
followed by a case analysis on the values of the arguments. *)
(** ** Casts and truth values *)
Inductive classify_cast_cases : Type :=
| cast_case_pointer (**r between pointer types or intptr_t types *)
| cast_case_i2i (sz2:intsize) (si2:signedness) (**r int -> int *)
| cast_case_f2f (**r double -> double *)
| cast_case_s2s (**r single -> single *)
| cast_case_f2s (**r double -> single *)
| cast_case_s2f (**r single -> double *)
| cast_case_i2f (si1: signedness) (**r int -> double *)
| cast_case_i2s (si1: signedness) (**r int -> single *)
| cast_case_f2i (sz2:intsize) (si2:signedness) (**r double -> int *)
| cast_case_s2i (sz2:intsize) (si2:signedness) (**r single -> int *)
| cast_case_l2l (**r long -> long *)
| cast_case_i2l (si1: signedness) (**r int -> long *)
| cast_case_l2i (sz2: intsize) (si2: signedness) (**r long -> int *)
| cast_case_l2f (si1: signedness) (**r long -> double *)
| cast_case_l2s (si1: signedness) (**r long -> single *)
| cast_case_f2l (si2:signedness) (**r double -> long *)
| cast_case_s2l (si2:signedness) (**r single -> long *)
| cast_case_i2bool (**r int -> bool *)
| cast_case_l2bool (**r long -> bool *)
| cast_case_f2bool (**r double -> bool *)
| cast_case_s2bool (**r single -> bool *)
| cast_case_struct (id1 id2: ident) (**r struct -> struct *)
| cast_case_union (id1 id2: ident) (**r union -> union *)
| cast_case_void (**r any -> void *)
| cast_case_default.
Definition classify_cast (tfrom tto: type) : classify_cast_cases :=
match tto, tfrom with
(* To [void] *)
| Tvoid, _ => cast_case_void
(* To [_Bool] *)
| Tint IBool _ _, Tint _ _ _ => cast_case_i2bool
| Tint IBool _ _, Tlong _ _ => cast_case_l2bool
| Tint IBool _ _, Tfloat F64 _ => cast_case_f2bool
| Tint IBool _ _, Tfloat F32 _ => cast_case_s2bool
| Tint IBool _ _, (Tpointer _ _ | Tarray _ _ _ | Tfunction _ _ _) =>
if Archi.ptr64 then cast_case_l2bool else cast_case_i2bool
(* To [int] other than [_Bool] *)
| Tint sz2 si2 _, Tint _ _ _ =>
if Archi.ptr64 then cast_case_i2i sz2 si2
else if intsize_eq sz2 I32 then cast_case_pointer
else cast_case_i2i sz2 si2
| Tint sz2 si2 _, Tlong _ _ => cast_case_l2i sz2 si2
| Tint sz2 si2 _, Tfloat F64 _ => cast_case_f2i sz2 si2
| Tint sz2 si2 _, Tfloat F32 _ => cast_case_s2i sz2 si2
| Tint sz2 si2 _, (Tpointer _ _ | Tarray _ _ _ | Tfunction _ _ _) =>
if Archi.ptr64 then cast_case_l2i sz2 si2
else if intsize_eq sz2 I32 then cast_case_pointer
else cast_case_i2i sz2 si2
(* To [long] *)
| Tlong _ _, Tlong _ _ =>
if Archi.ptr64 then cast_case_pointer else cast_case_l2l
| Tlong _ _, Tint sz1 si1 _ => cast_case_i2l si1
| Tlong si2 _, Tfloat F64 _ => cast_case_f2l si2
| Tlong si2 _, Tfloat F32 _ => cast_case_s2l si2
| Tlong si2 _, (Tpointer _ _ | Tarray _ _ _ | Tfunction _ _ _) =>
if Archi.ptr64 then cast_case_pointer else cast_case_i2l si2
(* To [float] *)
| Tfloat F64 _, Tint sz1 si1 _ => cast_case_i2f si1
| Tfloat F32 _, Tint sz1 si1 _ => cast_case_i2s si1
| Tfloat F64 _, Tlong si1 _ => cast_case_l2f si1
| Tfloat F32 _, Tlong si1 _ => cast_case_l2s si1
| Tfloat F64 _, Tfloat F64 _ => cast_case_f2f
| Tfloat F32 _, Tfloat F32 _ => cast_case_s2s
| Tfloat F64 _, Tfloat F32 _ => cast_case_s2f
| Tfloat F32 _, Tfloat F64 _ => cast_case_f2s
(* To pointer types *)
| Tpointer _ _, Tint _ si _ =>
if Archi.ptr64 then cast_case_i2l si else cast_case_pointer
| Tpointer _ _, Tlong _ _ =>
if Archi.ptr64 then cast_case_pointer else cast_case_l2i I32 Unsigned
| Tpointer _ _, (Tpointer _ _ | Tarray _ _ _ | Tfunction _ _ _) => cast_case_pointer
(* To struct or union types *)
| Tstruct id2 _, Tstruct id1 _ => cast_case_struct id1 id2
| Tunion id2 _, Tunion id1 _ => cast_case_union id1 id2
(* Catch-all *)
| _, _ => cast_case_default
end.
(** Semantics of casts. [sem_cast v1 t1 t2 m = Some v2] if value [v1],
viewed with static type [t1], can be converted to type [t2],
resulting in value [v2]. *)
Definition cast_int_int (sz: intsize) (sg: signedness) (i: int) : int :=
match sz, sg with
| I8, Signed => Int.sign_ext 8 i
| I8, Unsigned => Int.zero_ext 8 i
| I16, Signed => Int.sign_ext 16 i
| I16, Unsigned => Int.zero_ext 16 i
| I32, _ => i
| IBool, _ => if Int.eq i Int.zero then Int.zero else Int.one
end.
Definition cast_int_float (si: signedness) (i: int) : float :=
match si with
| Signed => Float.of_int i
| Unsigned => Float.of_intu i
end.
Definition cast_float_int (si : signedness) (f: float) : option int :=
match si with
| Signed => Float.to_int f
| Unsigned => Float.to_intu f
end.
Definition cast_int_single (si: signedness) (i: int) : float32 :=
match si with
| Signed => Float32.of_int i
| Unsigned => Float32.of_intu i
end.
Definition cast_single_int (si : signedness) (f: float32) : option int :=
match si with
| Signed => Float32.to_int f
| Unsigned => Float32.to_intu f
end.
Definition cast_int_long (si: signedness) (i: int) : int64 :=
match si with
| Signed => Int64.repr (Int.signed i)
| Unsigned => Int64.repr (Int.unsigned i)
end.
Definition cast_long_float (si: signedness) (i: int64) : float :=
match si with
| Signed => Float.of_long i
| Unsigned => Float.of_longu i
end.
Definition cast_long_single (si: signedness) (i: int64) : float32 :=
match si with
| Signed => Float32.of_long i
| Unsigned => Float32.of_longu i
end.
Definition cast_float_long (si : signedness) (f: float) : option int64 :=
match si with
| Signed => Float.to_long f
| Unsigned => Float.to_longu f
end.
Definition cast_single_long (si : signedness) (f: float32) : option int64 :=
match si with
| Signed => Float32.to_long f
| Unsigned => Float32.to_longu f
end.
Definition sem_cast (v: val) (t1 t2: type) : option val :=
match classify_cast t1 t2 with
| cast_case_pointer =>
match v with
| Vptr _ _ => Some v
| Vint _ => if Archi.ptr64 then None else Some v
| Vlong _ => if Archi.ptr64 then Some v else None
| _ => None
end
| cast_case_i2i sz2 si2 =>
match v with
| Vint i => Some (Vint (cast_int_int sz2 si2 i))
| _ => None
end
| cast_case_f2f =>
match v with
| Vfloat f => Some (Vfloat f)
| _ => None
end
| cast_case_s2s =>
match v with
| Vsingle f => Some (Vsingle f)
| _ => None
end
| cast_case_s2f =>
match v with
| Vsingle f => Some (Vfloat (Float.of_single f))
| _ => None
end
| cast_case_f2s =>
match v with
| Vfloat f => Some (Vsingle (Float.to_single f))
| _ => None
end
| cast_case_i2f si1 =>
match v with
| Vint i => Some (Vfloat (cast_int_float si1 i))
| _ => None
end
| cast_case_i2s si1 =>
match v with
| Vint i => Some (Vsingle (cast_int_single si1 i))
| _ => None
end
| cast_case_f2i sz2 si2 =>
match v with
| Vfloat f =>
match cast_float_int si2 f with
| Some i => Some (Vint (cast_int_int sz2 si2 i))
| None => None
end
| _ => None
end
| cast_case_s2i sz2 si2 =>
match v with
| Vsingle f =>
match cast_single_int si2 f with
| Some i => Some (Vint (cast_int_int sz2 si2 i))
| None => None
end
| _ => None
end
| cast_case_i2bool =>
match v with
| Vint n =>
Some(Vint(if Int.eq n Int.zero then Int.zero else Int.one))
| _ => None
end
| cast_case_l2bool =>
match v with
| Vlong n =>
Some(Vint(if Int64.eq n Int64.zero then Int.zero else Int.one))
| Vptr b ofs => None
| _ => None
end
| cast_case_f2bool =>
match v with
| Vfloat f =>
Some(Vint(if Float.cmp Ceq f Float.zero then Int.zero else Int.one))
| _ => None
end
| cast_case_s2bool =>
match v with
| Vsingle f =>
Some(Vint(if Float32.cmp Ceq f Float32.zero then Int.zero else Int.one))
| _ => None
end
| cast_case_l2l =>
match v with
| Vlong n => Some (Vlong n)
| _ => None
end
| cast_case_i2l si =>
match v with
| Vint n => Some(Vlong (cast_int_long si n))
| _ => None
end
| cast_case_l2i sz si =>
match v with
| Vlong n => Some(Vint (cast_int_int sz si (Int.repr (Int64.unsigned n))))
| _ => None
end
| cast_case_l2f si1 =>
match v with
| Vlong i => Some (Vfloat (cast_long_float si1 i))
| _ => None
end
| cast_case_l2s si1 =>
match v with
| Vlong i => Some (Vsingle (cast_long_single si1 i))
| _ => None
end
| cast_case_f2l si2 =>
match v with
| Vfloat f =>
match cast_float_long si2 f with
| Some i => Some (Vlong i)
| None => None
end
| _ => None
end
| cast_case_s2l si2 =>
match v with
| Vsingle f =>
match cast_single_long si2 f with
| Some i => Some (Vlong i)
| None => None
end
| _ => None
end
| cast_case_struct id1 id2 =>
match v with
| Vptr b ofs =>
if ident_eq id1 id2 then Some v else None
| _ => None
end
| cast_case_union id1 id2 =>
match v with
| Vptr b ofs =>
if ident_eq id1 id2 then Some v else None
| _ => None
end
| cast_case_void =>
Some v
| cast_case_default =>
None
end.
(** The following describes types that can be interpreted as a boolean:
integers, floats, pointers. It is used for the semantics of
the [!] and [?] operators, as well as the [if], [while],
and [for] statements. *)
Inductive classify_bool_cases : Type :=
| bool_case_i (**r integer *)
| bool_case_l (**r long *)
| bool_case_f (**r double float *)
| bool_case_s (**r single float *)
| bool_default.
Definition classify_bool (ty: type) : classify_bool_cases :=
match typeconv ty with
| Tint _ _ _ => bool_case_i
| Tpointer _ _ => if Archi.ptr64 then bool_case_l else bool_case_i
| Tfloat F64 _ => bool_case_f
| Tfloat F32 _ => bool_case_s
| Tlong _ _ => bool_case_l
| _ => bool_default
end.
(** Interpretation of values as truth values.
Non-zero integers, non-zero floats and non-null pointers are
considered as true. The integer zero (which also represents
the null pointer) and the float 0.0 are false. *)
Definition bool_val (v: val) (t: type) : option bool :=
match classify_bool t with
| bool_case_i =>
match v with
| Vint n => Some (negb (Int.eq n Int.zero))
| Vptr b ofs => None
| _ => None
end
| bool_case_l =>
match v with
| Vlong n => Some (negb (Int64.eq n Int64.zero))
| Vptr b ofs => None
| _ => None
end
| bool_case_f =>
match v with
| Vfloat f => Some (negb (Float.cmp Ceq f Float.zero))
| _ => None
end
| bool_case_s =>
match v with
| Vsingle f => Some (negb (Float32.cmp Ceq f Float32.zero))
| _ => None
end
| bool_default => None
end.
(** ** Unary operators *)
(** *** Boolean negation *)
Definition sem_notbool (v: val) (ty: type): option val :=
option_map (fun b => Val.of_bool (negb b)) (bool_val v ty).
(** *** Opposite and absolute value *)
Inductive classify_neg_cases : Type :=
| neg_case_i(s: signedness) (**r int *)
| neg_case_f (**r double float *)
| neg_case_s (**r single float *)
| neg_case_l(s: signedness) (**r long *)
| neg_default.
Definition classify_neg (ty: type) : classify_neg_cases :=
match ty with
| Tint I32 Unsigned _ => neg_case_i Unsigned
| Tint _ _ _ => neg_case_i Signed
| Tfloat F64 _ => neg_case_f
| Tfloat F32 _ => neg_case_s
| Tlong si _ => neg_case_l si
| _ => neg_default
end.
Definition sem_neg (v: val) (ty: type) : option val :=
match classify_neg ty with
| neg_case_i sg =>
match v with
| Vint n => Some (Vint (Int.neg n))
| _ => None
end
| neg_case_f =>
match v with
| Vfloat f => Some (Vfloat (Float.neg f))
| _ => None
end
| neg_case_s =>
match v with
| Vsingle f => Some (Vsingle (Float32.neg f))
| _ => None
end
| neg_case_l sg =>
match v with
| Vlong n => Some (Vlong (Int64.neg n))
| _ => None
end
| neg_default => None
end.
Definition sem_absfloat (v: val) (ty: type) : option val :=
match classify_neg ty with
| neg_case_i sg =>
match v with
| Vint n => Some (Vfloat (Float.abs (cast_int_float sg n)))
| _ => None
end
| neg_case_f =>
match v with
| Vfloat f => Some (Vfloat (Float.abs f))
| _ => None
end
| neg_case_s =>
match v with
| Vsingle f => Some (Vfloat (Float.abs (Float.of_single f)))
| _ => None
end
| neg_case_l sg =>
match v with
| Vlong n => Some (Vfloat (Float.abs (cast_long_float sg n)))
| _ => None
end
| neg_default => None
end.
(** *** Bitwise complement *)
Inductive classify_notint_cases : Type :=
| notint_case_i(s: signedness) (**r int *)
| notint_case_l(s: signedness) (**r long *)
| notint_default.
Definition classify_notint (ty: type) : classify_notint_cases :=
match ty with
| Tint I32 Unsigned _ => notint_case_i Unsigned
| Tint _ _ _ => notint_case_i Signed
| Tlong si _ => notint_case_l si
| _ => notint_default
end.
Definition sem_notint (v: val) (ty: type): option val :=
match classify_notint ty with
| notint_case_i sg =>
match v with
| Vint n => Some (Vint (Int.not n))
| _ => None
end
| notint_case_l sg =>
match v with
| Vlong n => Some (Vlong (Int64.not n))
| _ => None
end
| notint_default => None
end.
(** ** Binary operators *)
(** For binary operations, the "usual binary conversions" consist in
- determining the type at which the operation is to be performed
(a form of least upper bound of the types of the two arguments);
- casting the two arguments to this common type;
- performing the operation at that type.
*)
Inductive binarith_cases: Type :=
| bin_case_i (s: signedness) (**r at int type *)
| bin_case_l (s: signedness) (**r at long int type *)
| bin_case_f (**r at double float type *)
| bin_case_s (**r at single float type *)
| bin_default. (**r error *)
Definition classify_binarith (ty1: type) (ty2: type) : binarith_cases :=
match ty1, ty2 with
| Tint I32 Unsigned _, Tint _ _ _ => bin_case_i Unsigned
| Tint _ _ _, Tint I32 Unsigned _ => bin_case_i Unsigned
| Tint _ _ _, Tint _ _ _ => bin_case_i Signed
| Tlong Signed _, Tlong Signed _ => bin_case_l Signed
| Tlong _ _, Tlong _ _ => bin_case_l Unsigned
| Tlong sg _, Tint _ _ _ => bin_case_l sg
| Tint _ _ _, Tlong sg _ => bin_case_l sg
| Tfloat F32 _, Tfloat F32 _ => bin_case_s
| Tfloat _ _, Tfloat _ _ => bin_case_f
| Tfloat F64 _, (Tint _ _ _ | Tlong _ _) => bin_case_f
| (Tint _ _ _ | Tlong _ _), Tfloat F64 _ => bin_case_f
| Tfloat F32 _, (Tint _ _ _ | Tlong _ _) => bin_case_s
| (Tint _ _ _ | Tlong _ _), Tfloat F32 _ => bin_case_s
| _, _ => bin_default
end.
(** The static type of the result. Both arguments are converted to this type
before the actual computation. *)
Definition binarith_type (c: binarith_cases) : type :=
match c with
| bin_case_i sg => Tint I32 sg noattr
| bin_case_l sg => Tlong sg noattr
| bin_case_f => Tfloat F64 noattr
| bin_case_s => Tfloat F32 noattr
| bin_default => Tvoid
end.
Definition sem_binarith
(sem_int: signedness -> int -> int -> option val)
(sem_long: signedness -> int64 -> int64 -> option val)
(sem_float: float -> float -> option val)
(sem_single: float32 -> float32 -> option val)
(v1: val) (t1: type) (v2: val) (t2: type) : option val :=
let c := classify_binarith t1 t2 in
let t := binarith_type c in
match sem_cast v1 t1 t with
| None => None
| Some v1' =>
match sem_cast v2 t2 t with
| None => None
| Some v2' =>
match c with
| bin_case_i sg =>
match v1', v2' with
| Vint n1, Vint n2 => sem_int sg n1 n2
| _, _ => None
end
| bin_case_f =>
match v1', v2' with
| Vfloat n1, Vfloat n2 => sem_float n1 n2
| _, _ => None
end
| bin_case_s =>
match v1', v2' with
| Vsingle n1, Vsingle n2 => sem_single n1 n2
| _, _ => None
end
| bin_case_l sg =>
match v1', v2' with
| Vlong n1, Vlong n2 => sem_long sg n1 n2
| _, _ => None
end
| bin_default => None
end end end.
(** *** Addition *)
Inductive classify_add_cases : Type :=
| add_case_pi (ty: type) (si: signedness) (**r pointer, int *)
| add_case_pl (ty: type) (**r pointer, long *)
| add_case_ip (si: signedness) (ty: type) (**r int, pointer *)
| add_case_lp (ty: type) (**r long, pointer *)
| add_default. (**r numerical type, numerical type *)
Definition classify_add (ty1: type) (ty2: type) :=
match typeconv ty1, typeconv ty2 with
| Tpointer ty _, Tint _ si _ => add_case_pi ty si
| Tpointer ty _, Tlong _ _ => add_case_pl ty
| Tint _ si _, Tpointer ty _ => add_case_ip si ty
| Tlong _ _, Tpointer ty _ => add_case_lp ty
| _, _ => add_default
end.
Definition ptrofs_of_int (si: signedness) (n: int) : ptrofs :=
match si with
| Signed => Ptrofs.of_ints n
| Unsigned => Ptrofs.of_intu n
end.
Definition sem_add_ptr_int (cenv: composite_env) (ty: type) (si: signedness) (v1 v2: val): option val :=
match v1, v2 with
| Vptr b1 ofs1, Vint n2 =>
let n2 := ptrofs_of_int si n2 in
Some (Vptr b1 (Ptrofs.add ofs1 (Ptrofs.mul (Ptrofs.repr (sizeof cenv ty)) n2)))
| Vint n1, Vint n2 =>
if Archi.ptr64 then None else Some (Vint (Int.add n1 (Int.mul (Int.repr (sizeof cenv ty)) n2)))
| Vlong n1, Vint n2 =>
let n2 := cast_int_long si n2 in
if Archi.ptr64 then Some (Vlong (Int64.add n1 (Int64.mul (Int64.repr (sizeof cenv ty)) n2))) else None
| _, _ => None
end.
Definition sem_add_ptr_long (cenv: composite_env) (ty: type) (v1 v2: val): option val :=
match v1, v2 with
| Vptr b1 ofs1, Vlong n2 =>
let n2 := Ptrofs.of_int64 n2 in
Some (Vptr b1 (Ptrofs.add ofs1 (Ptrofs.mul (Ptrofs.repr (sizeof cenv ty)) n2)))
| Vint n1, Vlong n2 =>
let n2 := Int.repr (Int64.unsigned n2) in
if Archi.ptr64 then None else Some (Vint (Int.add n1 (Int.mul (Int.repr (sizeof cenv ty)) n2)))
| Vlong n1, Vlong n2 =>
if Archi.ptr64 then Some (Vlong (Int64.add n1 (Int64.mul (Int64.repr (sizeof cenv ty)) n2))) else None
| _, _ => None
end.
Definition sem_add (cenv: composite_env) (v1:val) (t1:type) (v2: val) (t2:type) : option val :=
match classify_add t1 t2 with
| add_case_pi ty si => (**r pointer plus integer *)
sem_add_ptr_int cenv ty si v1 v2
| add_case_pl ty => (**r pointer plus long *)
sem_add_ptr_long cenv ty v1 v2
| add_case_ip si ty => (**r integer plus pointer *)
sem_add_ptr_int cenv ty si v2 v1
| add_case_lp ty => (**r long plus pointer *)
sem_add_ptr_long cenv ty v2 v1
| add_default =>
sem_binarith
(fun sg n1 n2 => Some(Vint(Int.add n1 n2)))
(fun sg n1 n2 => Some(Vlong(Int64.add n1 n2)))
(fun n1 n2 => Some(Vfloat(Float.add n1 n2)))
(fun n1 n2 => Some(Vsingle(Float32.add n1 n2)))
v1 t1 v2 t2
end.
(** *** Subtraction *)
Inductive classify_sub_cases : Type :=
| sub_case_pi (ty: type) (si: signedness) (**r pointer, int *)
| sub_case_pp (ty: type) (**r pointer, pointer *)
| sub_case_pl (ty: type) (**r pointer, long *)
| sub_default. (**r numerical type, numerical type *)
Definition classify_sub (ty1: type) (ty2: type) :=
match typeconv ty1, typeconv ty2 with
| Tpointer ty _, Tint _ si _ => sub_case_pi ty si
| Tpointer ty _ , Tpointer _ _ => sub_case_pp ty
| Tpointer ty _, Tlong _ _ => sub_case_pl ty
| _, _ => sub_default
end.
Definition sem_sub (cenv: composite_env) (v1:val) (t1:type) (v2: val) (t2:type) : option val :=
match classify_sub t1 t2 with
| sub_case_pi ty si => (**r pointer minus integer *)
match v1, v2 with
| Vptr b1 ofs1, Vint n2 =>
let n2 := ptrofs_of_int si n2 in
Some (Vptr b1 (Ptrofs.sub ofs1 (Ptrofs.mul (Ptrofs.repr (sizeof cenv ty)) n2)))
| Vint n1, Vint n2 =>
if Archi.ptr64 then None else Some (Vint (Int.sub n1 (Int.mul (Int.repr (sizeof cenv ty)) n2)))
| Vlong n1, Vint n2 =>
let n2 := cast_int_long si n2 in
if Archi.ptr64 then Some (Vlong (Int64.sub n1 (Int64.mul (Int64.repr (sizeof cenv ty)) n2))) else None
| _, _ => None
end
| sub_case_pl ty => (**r pointer minus long *)
match v1, v2 with
| Vptr b1 ofs1, Vlong n2 =>
let n2 := Ptrofs.of_int64 n2 in
Some (Vptr b1 (Ptrofs.sub ofs1 (Ptrofs.mul (Ptrofs.repr (sizeof cenv ty)) n2)))
| Vint n1, Vlong n2 =>
let n2 := Int.repr (Int64.unsigned n2) in
if Archi.ptr64 then None else Some (Vint (Int.sub n1 (Int.mul (Int.repr (sizeof cenv ty)) n2)))
| Vlong n1, Vlong n2 =>
if Archi.ptr64 then Some (Vlong (Int64.sub n1 (Int64.mul (Int64.repr (sizeof cenv ty)) n2))) else None
| _, _ => None
end
| sub_case_pp ty => (**r pointer minus pointer *)
match v1,v2 with
| Vptr b1 ofs1, Vptr b2 ofs2 =>
if eq_block b1 b2 then
let sz := sizeof cenv ty in
if zlt 0 sz && zle sz Ptrofs.max_signed
then Some (Vptrofs (Ptrofs.divs (Ptrofs.sub ofs1 ofs2) (Ptrofs.repr sz)))
else None
else None
| _, _ => None
end
| sub_default =>
sem_binarith
(fun sg n1 n2 => Some(Vint(Int.sub n1 n2)))
(fun sg n1 n2 => Some(Vlong(Int64.sub n1 n2)))
(fun n1 n2 => Some(Vfloat(Float.sub n1 n2)))
(fun n1 n2 => Some(Vsingle(Float32.sub n1 n2)))
v1 t1 v2 t2
end.
(** *** Multiplication, division, modulus *)
Definition sem_mul (v1:val) (t1:type) (v2: val) (t2:type) : option val :=
sem_binarith
(fun sg n1 n2 => Some(Vint(Int.mul n1 n2)))
(fun sg n1 n2 => Some(Vlong(Int64.mul n1 n2)))
(fun n1 n2 => Some(Vfloat(Float.mul n1 n2)))
(fun n1 n2 => Some(Vsingle(Float32.mul n1 n2)))
v1 t1 v2 t2.
Definition sem_div (v1:val) (t1:type) (v2: val) (t2:type) : option val :=
sem_binarith
(fun sg n1 n2 =>
match sg with
| Signed =>
if Int.eq n2 Int.zero
|| Int.eq n1 (Int.repr Int.min_signed) && Int.eq n2 Int.mone
then None else Some(Vint(Int.divs n1 n2))
| Unsigned =>
if Int.eq n2 Int.zero
then None else Some(Vint(Int.divu n1 n2))
end)
(fun sg n1 n2 =>
match sg with
| Signed =>
if Int64.eq n2 Int64.zero
|| Int64.eq n1 (Int64.repr Int64.min_signed) && Int64.eq n2 Int64.mone
then None else Some(Vlong(Int64.divs n1 n2))
| Unsigned =>
if Int64.eq n2 Int64.zero
then None else Some(Vlong(Int64.divu n1 n2))
end)
(fun n1 n2 => Some(Vfloat(Float.div n1 n2)))
(fun n1 n2 => Some(Vsingle(Float32.div n1 n2)))
v1 t1 v2 t2.
Definition sem_mod (v1:val) (t1:type) (v2: val) (t2:type) : option val :=
sem_binarith
(fun sg n1 n2 =>
match sg with
| Signed =>
if Int.eq n2 Int.zero
|| Int.eq n1 (Int.repr Int.min_signed) && Int.eq n2 Int.mone
then None else Some(Vint(Int.mods n1 n2))
| Unsigned =>
if Int.eq n2 Int.zero
then None else Some(Vint(Int.modu n1 n2))
end)
(fun sg n1 n2 =>
match sg with
| Signed =>
if Int64.eq n2 Int64.zero
|| Int64.eq n1 (Int64.repr Int64.min_signed) && Int64.eq n2 Int64.mone
then None else Some(Vlong(Int64.mods n1 n2))
| Unsigned =>
if Int64.eq n2 Int64.zero
then None else Some(Vlong(Int64.modu n1 n2))
end)
(fun n1 n2 => None)
(fun n1 n2 => None)
v1 t1 v2 t2.
Definition sem_and (v1:val) (t1:type) (v2: val) (t2:type) : option val :=
sem_binarith
(fun sg n1 n2 => Some(Vint(Int.and n1 n2)))
(fun sg n1 n2 => Some(Vlong(Int64.and n1 n2)))
(fun n1 n2 => None)
(fun n1 n2 => None)
v1 t1 v2 t2.
Definition sem_or (v1:val) (t1:type) (v2: val) (t2:type) : option val :=
sem_binarith
(fun sg n1 n2 => Some(Vint(Int.or n1 n2)))
(fun sg n1 n2 => Some(Vlong(Int64.or n1 n2)))
(fun n1 n2 => None)
(fun n1 n2 => None)
v1 t1 v2 t2.
Definition sem_xor (v1:val) (t1:type) (v2: val) (t2:type) : option val :=
sem_binarith
(fun sg n1 n2 => Some(Vint(Int.xor n1 n2)))
(fun sg n1 n2 => Some(Vlong(Int64.xor n1 n2)))
(fun n1 n2 => None)
(fun n1 n2 => None)
v1 t1 v2 t2.
(** *** Shifts *)
(** Shifts do not perform the usual binary conversions. Instead,
each argument is converted independently, and the signedness
of the result is always that of the first argument. *)
Inductive classify_shift_cases : Type:=
| shift_case_ii(s: signedness) (**r int , int *)
| shift_case_ll(s: signedness) (**r long, long *)
| shift_case_il(s: signedness) (**r int, long *)
| shift_case_li(s: signedness) (**r long, int *)
| shift_default.
Definition classify_shift (ty1: type) (ty2: type) :=
match typeconv ty1, typeconv ty2 with
| Tint I32 Unsigned _, Tint _ _ _ => shift_case_ii Unsigned
| Tint _ _ _, Tint _ _ _ => shift_case_ii Signed
| Tint I32 Unsigned _, Tlong _ _ => shift_case_il Unsigned
| Tint _ _ _, Tlong _ _ => shift_case_il Signed
| Tlong s _, Tint _ _ _ => shift_case_li s
| Tlong s _, Tlong _ _ => shift_case_ll s
| _,_ => shift_default
end.
Definition sem_shift
(sem_int: signedness -> int -> int -> int)
(sem_long: signedness -> int64 -> int64 -> int64)
(v1: val) (t1: type) (v2: val) (t2: type) : option val :=
match classify_shift t1 t2 with
| shift_case_ii sg =>
match v1, v2 with
| Vint n1, Vint n2 =>
if Int.ltu n2 Int.iwordsize
then Some(Vint(sem_int sg n1 n2)) else None
| _, _ => None
end
| shift_case_il sg =>
match v1, v2 with
| Vint n1, Vlong n2 =>
if Int64.ltu n2 (Int64.repr 32)
then Some(Vint(sem_int sg n1 (Int64.loword n2))) else None
| _, _ => None
end
| shift_case_li sg =>
match v1, v2 with
| Vlong n1, Vint n2 =>
if Int.ltu n2 Int64.iwordsize'
then Some(Vlong(sem_long sg n1 (Int64.repr (Int.unsigned n2)))) else None
| _, _ => None
end
| shift_case_ll sg =>
match v1, v2 with
| Vlong n1, Vlong n2 =>
if Int64.ltu n2 Int64.iwordsize
then Some(Vlong(sem_long sg n1 n2)) else None
| _, _ => None
end
| shift_default => None
end.
Definition sem_shl (v1:val) (t1:type) (v2: val) (t2:type) : option val :=
sem_shift
(fun sg n1 n2 => Int.shl n1 n2)
(fun sg n1 n2 => Int64.shl n1 n2)
v1 t1 v2 t2.
Definition sem_shr (v1:val) (t1:type) (v2: val) (t2:type) : option val :=
sem_shift
(fun sg n1 n2 => match sg with Signed => Int.shr n1 n2 | Unsigned => Int.shru n1 n2 end)
(fun sg n1 n2 => match sg with Signed => Int64.shr n1 n2 | Unsigned => Int64.shru n1 n2 end)
v1 t1 v2 t2.
(** *** Comparisons *)
Inductive classify_cmp_cases : Type :=
| cmp_case_pp (**r pointer, pointer *)
| cmp_case_pi (si: signedness) (**r pointer, int *)
| cmp_case_ip (si: signedness) (**r int, pointer *)
| cmp_case_pl (**r pointer, long *)
| cmp_case_lp (**r long, pointer *)
| cmp_default. (**r numerical, numerical *)
Definition classify_cmp (ty1: type) (ty2: type) :=
match typeconv ty1, typeconv ty2 with
| Tpointer _ _ , Tpointer _ _ => cmp_case_pp
| Tpointer _ _ , Tint _ si _ => cmp_case_pi si
| Tint _ si _, Tpointer _ _ => cmp_case_ip si
| Tpointer _ _ , Tlong _ _ => cmp_case_pl
| Tlong _ _ , Tpointer _ _ => cmp_case_lp
| _, _ => cmp_default
end.
Definition sem_cmp (c:comparison)
(v1: val) (t1: type) (v2: val) (t2: type)
: option val :=
match classify_cmp t1 t2 with
| cmp_case_pp => None
| cmp_case_pi si => None
| cmp_case_ip si => None
| cmp_case_pl => None
| cmp_case_lp => None
| cmp_default =>
sem_binarith
(fun sg n1 n2 =>
Some(Val.of_bool(match sg with Signed => Int.cmp c n1 n2 | Unsigned => Int.cmpu c n1 n2 end)))
(fun sg n1 n2 =>
Some(Val.of_bool(match sg with Signed => Int64.cmp c n1 n2 | Unsigned => Int64.cmpu c n1 n2 end)))
(fun n1 n2 =>
Some(Val.of_bool(Float.cmp c n1 n2)))
(fun n1 n2 =>
Some(Val.of_bool(Float32.cmp c n1 n2)))
v1 t1 v2 t2
end.
(** ** Function applications *)
Inductive classify_fun_cases : Type :=
| fun_case_f (targs: typelist) (tres: type) (cc: calling_convention) (**r (pointer to) function *)
| fun_default.
Definition classify_fun (ty: type) :=
match ty with
| Tfunction args res cc => fun_case_f args res cc
| Tpointer (Tfunction args res cc) _ => fun_case_f args res cc
| _ => fun_default
end.
(** ** Argument of a [switch] statement *)
Inductive classify_switch_cases : Type :=
| switch_case_i
| switch_case_l
| switch_default.
Definition classify_switch (ty: type) :=
match ty with
| Tint _ _ _ => switch_case_i
| Tlong _ _ => switch_case_l
| _ => switch_default
end.
Definition sem_switch_arg (v: val) (ty: type): option Z :=
match classify_switch ty with
| switch_case_i =>
match v with Vint n => Some(Int.unsigned n) | _ => None end
| switch_case_l =>
match v with Vlong n => Some(Int64.unsigned n) | _ => None end
| switch_default =>
None
end.
(** * Combined semantics of unary and binary operators *)
Definition sem_unary_operation
(op: unary_operation) (v: val) (ty: type) : option val :=
match op with
| Onotbool => sem_notbool v ty
| Onotint => sem_notint v ty
| Oneg => sem_neg v ty
| Oabsfloat => sem_absfloat v ty
end.
Definition sem_binary_operation
(cenv: composite_env)
(op: binary_operation)
(v1: val) (t1: type) (v2: val) (t2:type)
: option val :=
match op with
| Oadd => sem_add cenv v1 t1 v2 t2
| Osub => sem_sub cenv v1 t1 v2 t2
| Omul => sem_mul v1 t1 v2 t2
| Omod => sem_mod v1 t1 v2 t2
| Odiv => sem_div v1 t1 v2 t2
| Oand => sem_and v1 t1 v2 t2
| Oor => sem_or v1 t1 v2 t2
| Oxor => sem_xor v1 t1 v2 t2
| Oshl => sem_shl v1 t1 v2 t2
| Oshr => sem_shr v1 t1 v2 t2
| Oeq => sem_cmp Ceq v1 t1 v2 t2
| One => sem_cmp Cne v1 t1 v2 t2
| Olt => sem_cmp Clt v1 t1 v2 t2
| Ogt => sem_cmp Cgt v1 t1 v2 t2
| Ole => sem_cmp Cle v1 t1 v2 t2
| Oge => sem_cmp Cge v1 t1 v2 t2